University of Groningen
Epidemiological Typing of Serratia marcescens Isolates by Whole-Genome MultilocusSequence TypingRossen, John W. A.; Dombrecht, Jill; Vanfleteren, Diederik; De Bruyne, Katrien; van Belkum,Alex; Rosema, Sigrid; Lokate, Mariette; Bathoorn, Erik; Reuter, Sandra; Grundmann, HajoPublished in:Journal of Clinical Microbiology
DOI:10.1128/JCM.01652-18
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Citation for published version (APA):Rossen, J. W. A., Dombrecht, J., Vanfleteren, D., De Bruyne, K., van Belkum, A., Rosema, S., Lokate, M.,Bathoorn, E., Reuter, S., Grundmann, H., Ertel, J., Higgins, P. G., & Seifert, H. (2019). EpidemiologicalTyping of Serratia marcescens Isolates by Whole-Genome Multilocus Sequence Typing. Journal of ClinicalMicrobiology, 57(4), [e01652-18]. https://doi.org/10.1128/JCM.01652-18
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https://doi.org/10.1128/JCM.01652-18https://research.rug.nl/en/publications/epidemiological-typing-of-serratia-marcescens-isolates-by-wholegenome-multilocus-sequence-typing(e9880171-a86c-49e7-adf1-8ebda5d69b02).htmlhttps://doi.org/10.1128/JCM.01652-18
1
EPIDEMIOLOGICAL TYPING OF SERRATIA MARCESCENS 1
BY WHOLE GENOME MULTI-LOCUS SEQUENCE TYPING 2
3
John W.A. Rossen1, Jill Dombrecht2, Diederik Vanfleteren2, Katrien De Bruyne2, 4
Alex van Belkum3,*, Sigrid Rosema1 , Mariette Lokate1, Erik Bathoorn1, 5
Sandra Reuter4, Hajo Grundmann4, 6
Julia Ertel5,6, Paul G. Higgins5,6 and Harald Seifert5,6 7
8
1 University of Groningen, 9
University Medical Center Groningen, 10
Department of Medical Microbiology and Infection Prevention, Mail Code EB80, 11
Hanzeplein 1, 9713 GZ Groningen, The Netherlands. 12
2bioMérieux, Data Analytics Department, Applied Maths NV, 13
Keistraat 120, 9830 St-Martens-Latem, Belgium. 14
3bioMérieux, Data Analytics Department, 15
3 Route de Port Michaud, 38390 La Balme Les Grottes, France. 16
4Medical Center – University of Freiburg, Faculty of Medicine, 17
Institute for Infection Prevention and Hospital Epidemiology 18
Breisacher Str. 115 B, 79106 Freiburg, Germany 19
5Institute for Medical Microbiology, Immunology and Hygiene, 20
University of Cologne, Goldenfelsstrasse 19-21, 50935 Köln, Germany 21
6German Centre for Infection Research (DZIF), 22
Partner Site Bonn-Cologne, Germany 23
24
*Communicating author: bioMerieux Data Analytics Department, 3 Route de Port 25
Michaud, La Balme Les Grottes, France 26
e-mail [email protected] 27
phone +33609487905 28
29
Key words: Serratia marcescens – outbreak management – BioNumerics™ – 30
neonatal intensive care – molecular typing - whole genome sequencing (WGS) – 31
whole genome Multi Locus Sequence Typing (wgMLST). 32
33
JCM Accepted Manuscript Posted Online 6 February 2019J. Clin. Microbiol. doi:10.1128/JCM.01652-18Copyright © 2019 American Society for Microbiology. All Rights Reserved.
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ABSTRACT 34
Serratia marcescens is an opportunistic bacterial pathogen. It is notorious for its 35
increasing antimicrobial resistance and its potential to cause outbreaks of 36
colonization and infections predominantly in neonatal intensive care units (NICUs). 37
There, its spread requires rapid infection control response. In order to understand its 38
spread, detailed molecular typing is key. We present a whole genome multi-locus 39
sequence typing (wgMLST) method for S. marcescens. Using a set of 299 publicly 40
available whole genome sequences (WGS) we developed an initial wgMLST system 41
consisting of 9377 gene loci. This included 1455 loci occurring in all reference 42
genomes and 7922 accessory loci. This closed system was validated using three 43
geographically diverse collections of S. marcescens consisting of 111 clinical 44
isolates implicated in nosocomial dissemination events in three hospitals. The 45
validation procedure showed a full match between epidemiological data and the 46
wgMLST analyses. We set the cut-off value for epidemiological (non-)relatedness at 47
20 different alleles, although for the majority of outbreak-clustered isolates this 48
difference was limited to 4 alleles. This shows that the wgMLST system for S. 49
marcescens provides prospects of successful future monitoring for the 50
epidemiological containment of this opportunistic pathogen. 51
52
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INTRODUCTION 53
The new Gold Standard in microbial epidemiology is genome sequencing. The use 54
of whole genome (draft) sequences (WGS) to compare bacterial isolates in detail, 55
and to delineate their spread, is based on either the detection of single nucleotide 56
variants or polymorphisms (SNVs and SNPs) or on the assessment of overall gene 57
content including allelic differences between strains by whole genome multi-locus 58
sequence typing (wgMLST) (1-4). Both methods have their advantages and 59
disadvantages. Where SNP analysis may have a higher intrinsic discriminatory 60
power (since it covers coding and non-coding regions) and better resolves the 61
ancestral relationship between lineages, wgMLST usually provides a more stable, 62
generically applicable system, with results that are easier to translate into relevant 63
epidemiological differences between isolates. wgMLST schemes have been 64
developed for a multitude of microbial organisms, with the main driver being the 65
development of a universal “typing language” (5-7). This will facilitate the monitoring 66
of local, institutional spread of certain pathogens but will also extend into regional, 67
national, international, and possibly even global monitoring for the dissemination of 68
given bacterial strain types (8-10). This will aid communication in international public 69
health management and should in the end lead to early recognition of the 70
emergence and spread of pathogenic microbial strains. Furthermore, this is of 71
importance in the current era of multi-drug resistant bacteria and their global 72
dispersal promoted by human travelling, international patient transfer, nosocomial 73
transmission, and excessive use of antimicrobials. 74
Serratia marcescens is a bacterial pathogen for which no wgMLST scheme has been 75
defined yet. S. marcescens is notorious for its pathogenicity in plants (11) but also in 76
preterm neonates (12,13). Therefore, setting up a robust epidemiological wgMLST 77
typing scheme is essential for monitoring and interrupting outbreaks in neonatal 78
intensive care units (NICU) as well as other medical settings. In addition, S. 79
marcescens is capable of efficiently acquiring multiple resistance determinants (that 80
are unreliable epidemiological markers) which adds to its clinical relevance (14-18). 81
We have developed a proprietary wgMLST toolbox for S. marcescens based on 82
publicly available WGS data. We have validated the scheme using epidemiologically 83
related isolates collected during recent outbreaks of colonization and infection in 84
NICUs in both Dutch and German teaching hospitals. 85
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86
MATERIALS AND METHODS 87
Strains: Clinical S. marcescens isolates were obtained from three different 88
institutions in Groningen (The Netherlands; n=41), Cologne (Germany; n=19) and 89
Freiburg (Germany; n=51), respectively. 90
The 41 isolates from the University Medical Center Groningen were obtained 91
between 2014 and 2017 from 38 patients of which 4 were adults in non-pediatric 92
wards (2 in cardiology, 1 in orthopedics and 1 in obstetrics), 2 were from children > 93
12 year in the pediatric ICU (PICU), 1 from a child > 18 months and the others from 94
children < 6 months either on the pediatric special care unit (n=1), the pediatric 95
general surgery ward (n=2), the PICU (n=2), or the NICU (n=26). From three patients 96
two isolates were sequenced. In one case, in addition to a positive culture from a 97
rectal swab of the patient also an isolate was cultured from the intravenous line, but 98
this isolate appeared to be a S. liquefaciens, originally misidentified as S. 99
marcescens by conventional diagnostic methods. All other isolates were cultured 100
from patients in the NICU using growth-based microbiology technology (see Figure 1 101
for additional details on strain origin). The 19 isolates from Cologne were isolated 102
between 2014 and 2017 and all originate from NICUs, PICUs and general wards. 103
The age of the patients varied between 4 days and 11 months. The collection of 104
isolates consisted of 5 epidemiologically related transmission clusters and 2 105
singleton isolates (see Figure 2 for additional details). The 51 isolates from Freiburg 106
mostly originated from the local NICU (n=39) with patient age varying between 0 and 107
12 weeks. Seven environmental isolates were included for comparative reasons and 108
to gauge the relevance of environmental spread. For several patients (A to H, n=8) 109
multiple isolates were included in order to define basic levels of intra-patient 110
variability of S. marcescens (see Figure 3 for additional details). 111
Isolates were either directly processed or stored at -80oC in glycerol-containing 112
media until culture for DNA isolation and genome sequencing. In addition to the 113
WGS data, clinical and epidemiological data were included. Metadata included, but 114
were not limited to, isolation dates, outbreak associations, patients’ gender and age, 115
type (and outcome) of infections, specimen types submitted for microbiological 116
analyses, location of the ward and whether local typing data obtained previously 117
were available. 118
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DNA isolation: DNA was extracted using the Ultraclean Microbial DNA isolation kit 119
(MoBio Laboratories, Carlsbad, CA, USA) or the MagAttract HMW DNA Isolation kit, 120
in both cases following the manufacturer's instructions (Qiagen, Hilden, Germany) 121
and quantified using a NanoDrop 2000c spectrophotometer (Thermo Fisher 122
Scientific Inc, Waltham, MA, USA) and/or the Qubit dsDNA HS assay (Thermo 123
Fisher Scientific GmbH, Schwerte, Germany). 124
Genome sequencing: DNA libraries were prepared using the Nextera XT library 125
preparation kit and the Nextera XT v2 index kit (Illumina, San Diego, CA, USA). The 126
library was sequenced on a MiSeq, using the reagent kit v2 generating 250-bp 127
paired-end reads. Supplementary Tables 1A to 1C disclose the quality parameters 128
for the sequences determined. All WGS included met with the required quality 129
criteria and all primary sequences were deposited in the public domain (ENA project 130
numbers PRJEB28358 and PRJEB28681). 131
Development of the wgMLST scheme: A scheme for wgMLST of S. marcescens 132
was developed using publicly available WGS data for this species (June 2017), and 133
will be made commercially available through a plugin in BioNumerics™ (Applied 134
Maths NV, St-Martens-Latem, Belgium). The scheme is intended to facilitate 135
detection of subtype- or outbreak-specific markers. Using a selection of 299 136
annotated, publicly available reference genomes which were assumed to capture the 137
diversity within S. marcescens, a pan-genomic scheme with high discriminatory 138
power was developed (see Supplementary Table 2 for a list of all WGS included). 139
Starting from the reference genomes, our scheme creation procedure uses a 140
sampling-based multi-reciprocal BLAST procedure to determine those sets of alleles 141
that make up the stable loci in the pan-genome. A per-locus allele assessment 142
procedure then determines the central prototype allele, and thus the definition of the 143
locus. The wgMLST scheme for S. marcescens was tested, validated and approved 144
by epidemiological and microbiological analyses using information on the strain 145
collections from Groningen, Cologne and Freiburg. 146
Bioinformatic analyses: De novo genome assembly for all WGS was performed 147
using SPAdes 3.7.1. All de novo calculations were run on the cloud-based 148
calculation engine that comes with BioNumerics™ 7.6.3. wgMLST analysis was also 149
performed using the BioNumerics™ cloud-based calculation engine. Alleles were 150
identified by both an assembly-free k-mer based approach using the raw reads and 151
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an assembly-based BLAST approach. Identification was done against the S. 152
marcescens wgMLST database in BioNumerics™. Categorical coefficients were 153
used for defining similarity levels and Unweighted Pair Group Method with Arithmetic 154
Mean (UPGMA) was used as clustering algorithm. Minimum spanning trees (MST) 155
were constructed using the wgMLST allelic profiles as input data. The size of the 156
nodes was chosen proportional to the number of isolates in the nodes (i.e. isolates 157
with the same allelic profiles). Branch lengths reflect the number of allele differences 158
between the isolates in the connected nodes. 159
160
RESULTS 161
A new system for wgMLST for S. marcescens: In total, 299 reference genome 162
sequences were included while building the wgMLST scheme. These displayed a 163
conformity between 85% and 97% after constructing the scheme and showed an 164
average of 95% global coverage of the included loci. The scheme was validated in 165
August 2017 on the basis of 373 sequence read archives (SRA), which included all 166
Illumina data sets publicly available as of 28 August 2017. In this way, a total of 167
9,377 loci were added to the scheme, including 1455 loci which were present in all 168
references and 7922 accessory loci. The wgMLST scheme had high discriminatory 169
power and allowed for the detection of markers specific for S. marcescens subtypes 170
or outbreak strains, thus enabling powerful classification and outbreak definition (see 171
Figure 4C). The two allele detection procedures (either assembly-based or 172
assembly-free) performed fast and reliable allele calling for cluster detection. Figure 173
4A indicates the diversity within the reference genome set, and provides an overview 174
of the number of clusters as function of the similarity cutoff value, indicating the 175
presence of both distant and highly related isolates in the reference set of 299 176
strains. Figure 4B depicts the number of pairwise allelic differences and the 177
frequency of their occurrence peaking at about 4000 allelic differences given the 178
current wgMLST scheme complexity. Figure 4C shows a global perspective of the 179
genomic diversity among the references used to build the wgMLST scheme, where 180
all circles identify distinct wgMLST types (as also semi-quantified by the number of 181
allelic differences quantified on the branches) and the colored blocks identify isolates 182
of more closely related and sometimes indistinguishable genomic sequences. This 183
confirms our assumption that the genome sequences obtained from the public 184
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domain show significant levels of diversity allowing them to serve as reference of 185
genomic variability. Overall, the quality parameters indicate that the scheme covers 186
the diversity within the species and provides sufficient resolving power for 187
distinguishing even closely related bacterial isolates. Finally, it seems that the 188
population structure of S. marcescens is largely genetically diverse with many 189
singletons present. However, there seem to be indications for the successful 190
expansion of clones (colored circles, Figure 4C). 191
Strain characteristics and outbreak features: It has to be stated that only one 192
patient died as a consequence of S. marcescens colonization/infection. Also, 193
presence was mostly due to colonization and real infection was only apparent in a 194
limited number of cases (Groningen 9 of 38 patients (24%); Cologne 2/16 (13%); 195
Freiburg 6/23 (26%) (one sample of unknown origin)). Overall, 22% patients had an 196
infection. 197
Groningen outbreak analyses: Forty-one clinical isolates were obtained 198
from 38 patients in the University Medical Center Groningen (UMCG). The wgMLST 199
analysis detected a small cluster of related isolates: five isolates obtained from three 200
patients in May-June in 2015 (cluster 0003 in Figure 1). From one patient two 201
isolates from the rectal swab appeared to be 100% wgMLST identical and from the 202
other patient the isolate found in the blood was identical to the one found in the rectal 203
swab. In addition, a larger cluster was found containing isolates, all from different 204
patients, from a protracted outbreak in August-November 2014 (cluster 0005 in 205
Figure 1). The single invasive isolate that was isolated during this episode was 206
indistinguishable from the other isolates. In addition, four suspected cases of single 207
transmission events involving two patients were confirmed as well (clusters 0001, 208
0002, 0004, 0006 and 0007 in Figure 1). Hence, the clustering aligns very well with 209
the prior epidemiological scenarios. The 0002 cluster contained two separate 210
isolates from the same patient, showing the reproducibility of the method. All isolates 211
contained the aminoglycoside resistance-associated gene aac(6’)-I-C and about half 212
of them contained the tetracycline resistance determinant Tet (41). A single multi-213
resistant isolate was cultured from the synovial fluid of an elderly female nursed at 214
the orthopedics department. The origin of this strain is not clear. 215
Cologne outbreak analyses: wgMLST analysis of the 19 isolates from the 216
Cologne University hospital correctly defined the anticipated clustering and identified 217
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two main outbreak clusters and three cases where inter-patient transfer was already 218
suspected (Cologne-1 to Cologne-5). The two singleton isolates were separated 219
from all of the other isolates. Figure 2 summarizes the overall data and sketches the 220
outbreak scenarios also showing that all related isolates were 100% identical at the 221
wgMLST level. One of the singleton isolates contained at least 8 different resistance 222
genes. 223
Freiburg outbreak analyses: The collection of isolates derived from the 224
laboratory in the Freiburg University hospital contained 47 out of 51 isolates that 225
were nearly indistinguishable by wgMLST (Figure 3, green boxes), indicating a local 226
outbreak which occurred in October and November 2015 involving 19 patients and 7 227
environmental isolates. Additionally, two isolates were identified (red boxes, Figure 3) 228
that were not distinguished by wgMLST, reflecting a single, known transmission 229
event of a different strain type outside the NICU. Most of the outbreak isolates were 230
considered to represent colonization rather than infection or bacteremia (16/19 231
patients). All serial isolates obtained from individual patients were identical at the 232
wgMLST level. Only in case of patients F and H small differences were documented 233
but within the boundaries of the epidemiological cut-off value. Finally, the 234
environmental isolates all fell within the same outbreak category. 235
Minimum spanning trees: Figure 5 displays the minimum spanning trees for 236
the three studies and there is good concordance with the UPGMA trees in Figures 1-237
3. The number of allele differences ranged between 0 and 4 for the epidemiologically 238
defined strain clusters with two exceptions. There is only a single strain in the 239
Freiburg cluster that differs by 18 alleles from its counterparts. This suggests that a 240
cut-off value of
9
marcescens is less developed, and for this reason we developed a wgMLST scheme. 251
The system allowed for the adequate recognition of clonally related organisms and it 252
allowed for the detection of outbreak events. At the level of wgMLST the number of 253
changes between the most closely related isolates were less than twenty alleles 254
(given the time frame during which our outbreak related strains were captured), 255
although a significant fraction of the closely related genomes only differed by 0-4 256
alleles. This latter level of resolution does not allow for detailed epidemiological 257
tracing of spread from one patient to the other given the apparently low number of 258
changes associated with such transfers. We performed a limited number of wgSNP 259
analyses and, surprisingly, for the ten related isolates from Groningen, this did not 260
increase the resolution. The number of SNPs encountered between the ten isolates 261
ranged from zero to five, in the same range as the wgMLST variation and insufficient 262
to decipher transmission of strains between patients (data not shown). Of note, a 263
recent cgMLST study for Brucella melitensis revealed similar findings: 264
epidemiological cut off values for non-variance were defined as
10
examples brought forward by Martineau et al, a single outbreak was analyzed, where 284
we have now taken the method to a higher level including the development of a 285
dedicated wgMLST WGS database and an informatics tool for the semi-automated 286
analysis of potential outbreak scenarios. With turnaround calculation times of less 287
than 30 minutes per sample and simultaneous processing of up to 24 samples, high-288
powered wgMLST performance is guaranteed. Using BioNumerics™ and a cloud-289
based calculation engine, it provides a high-throughput environment that enables a 290
fast and simple outbreak analysis of WGS data for S. marcescens. The calculation 291
engine’s quality-controlled de novo assembly possibilities allow for rapid, push-292
button assembly of WGS data without the need of local computing power. In short, 293
even high resolution typing needs optimal epidemiological data and cannot stand on 294
its own. Although we here focus on patients in NICUs it should be emphasized that 295
genomic typing of S. marcescens will have wider implications as these bacteria infect 296
other risk groups as well (25,26). We acknowledge the fact that we are not disclosing 297
the precise methodology used for wgMLST scheme development since this module 298
will become available only in combination with BioNumerics™. 299
In conclusion, all laboratory-run typing methods, wgMLST included, are valuable in 300
the context of hospital-wide screening for pathogens but also for analyses of random 301
clinical isolates (27,28). wgMLST for S. marcescens has here been demonstrated to 302
be a promising epidemiological typing support tool. In combination with tools for 303
deciphering a genomic antibiogram and the presence of virulence genes, WGS by 304
NGS may help trace and follow outbreaks, understand the acquisition and spread of 305
resistance factors and explain the disease invoking potential for this not-to-be-306
underestimated human pathogen. 307
308
ACKNOWLEDGEMENTS 309
This work was done in collaboration with the European Society of Clinical 310
Microbiology and Infectious Diseases (ESCMID) Study Group on Genomic and 311
Molecular Diagnostics (ESGMD), and the ESCMID Study Group on Epidemiological 312
Markers (ESGEM), Basel, Switzerland. 313
314
TRANSPARENCY DECLARATION 315
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Alex van Belkum, Jill Dombrecht, Diederik Vanfleteren and Katrien De Bruyne are 316
employees of bioMérieux, a company designing, developing and selling infectious 317
disease diagnostics and hence have a business implication in this work. John 318
Rossen consults for IDbyDNA. All other authors declare no conflicts of interest and 319
have submitted the ICMJE Form for Disclosure of Potential Conflicts of Interest. 320
Conflicts that the editors consider relevant to the content of the manuscript have 321
been disclosed. No external financial support was provided for the studies presented 322
herein. 323
324
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MDR and XDR KPC-producing Serratia marcescens. Int J Antimicrob Agents 395
pii:S0924-8579(18)30219-X. doi: 10.1016/j.ijantimicag.2018.07.020. 396
19. Janowicz A, De Massis F, Ancora M, Cammà C, Patavino C, Battisti A, Prior K, 397
Harmsen D, Scholz H, Zilli K, Sacchini L, Di Giannatale E, Garofolo G. 2018. Core 398
Genome Multilocus Sequence Typing and Single Nucleotide Polymorphism Analysis 399
in the epidemiology of Brucella melitensis infections. J Clin Microbiol 56:e00517-18. 400
doi: 10.1128/JCM.00517-18. 401
20. Westblade LF, van Belkum A, Grundhoff A, Weinstock GM, Pamer EG, Pallen 402
MJ, Dunne WM Jr. 2016. Role of clinicogenomics in infectious disease diagnostics 403
and public health microbiology. J Clin Microbiol 54:1686-93. doi: 404
10.1128/JCM.02664-15. 405
21. Dunne WM Jr, Westblade LF, Ford B. 2012. Next-generation and whole-genome 406
sequencing in the diagnostic clinical microbiology laboratory. Eur J Clin Microbiol 407
Infect Dis 31:1719-26. doi: 10.1007/s10096-012-1641-7. 408
22. Huang YT, Cheng JF, Liu YT, Mao YC, Wu MS, Liu PY. 2018. Genome-based 409
analysis of virulence determinants of a Serratia marcescens strain from soft tissues 410
following a snake bite. Future Microbiol 13:331-43. doi: 10.2217/fmb-2017-0202. 411
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23. Iguchi A, Nagaya Y, Pradel E, Ooka T, Ogura Y, Katsura K, Kurokawa K, 412
Oshima K, Hattori M, Parkhill J, Sebaihia M, Coulthurst SJ, Gotoh N, Thomson NR, 413
Ewbank JJ, Hayashi T. 2014. Genome evolution and plasticity of Serratia 414
marcescens, an important multidrug-resistant nosocomial pathogen. Genome Biol 415
Evol 6:2096-110. doi: 10.1093/gbe/evu160. 416
24. Martineau C, Li X, Lalancette C, Perreault T, Fournier E, Tremblay J, Gonzales 417
M, Yergeau É, Quach C. 2018. Serratia marcescens outbreak in a neonatal intensive 418
care unit (NICU): new insights from next-generation sequencing applications. J Clin 419
Microbiol JCM.00235-18. doi: 10.1128/JCM.00235-18. 420
25. Leng P, Huang WL, He T, Wang YZ, Zhang HN. 2015. Outbreak of Serratia 421
marcescens postoperative infection traced to barbers and razors. J Hosp Infect 422
89:46-50. doi: 10.1016/j.jhin.2014.09.013. 423
26. Us E, Kutlu HH, Tekeli A, Ocal D, Cirpan S, Memikoglu KO. 2017. Wound and 424
soft tissue infections of Serratia marcescens in patients receiving wound care: A 425
health care-associated outbreak. Am J Infect Control 45(4):443-7. doi: 426
10.1016/j.ajic.2016.11.015. 427
27. Dawczynski K, Proquitté H, Roedel J, Edel B, Pfeifer Y, Hoyer H, Dobermann H, 428
Hagel S, Pletz MW. 2016. Intensified colonization screening according to the 429
recommendations of the German Commission for Hospital Hygiene and Infectious 430
Diseases Prevention (KRINKO): identification and containment of a Serratia 431
marcescens outbreak in the neonatal intensive care unit, Jena, Germany, 2013-2014. 432
Infection 44:739-46. 433
28. Åttman E, Korhonen P, Tammela O, Vuento R, Aittoniemi J, Syrjänen J, Mattila E, 434
Österblad M, Huttunen R. 2018. A Serratia marcescens outbreak in a neonatal 435
intensive care unit was successfully managed by rapid hospital hygiene interventions 436
and screening. Acta Paediatr 107:425-9. doi: 10.1111/apa.14132. 437
438
439
LEGENDS TO THE FIGURES 440
441
Figure 1 UPGMA tree of the pan-genomic allelic profiles (n=25) derived for S. 442
marcescens isolates from the University Medical Center Groningen, The Netherlands. 443
Outbreaks and transfer events identified prior to our study (0001-0007) are 444
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15
highlighted by color, with relevant microbiological, host-associated and 445
environmental metadata displayed to the right. The UPGMA tree which was built 446
using a similarity coefficient based on categorical values expressed as a percentage. 447
Strain UMCG-029, located at the bottom of the tree, represents S. liquefaciens, a 448
species only sharing about 2900 loci with the S. marcescens wgMLST scheme, as 449
opposed to 4300 loci that are typically detected in S. marcescens. 450
451
Figure 2 UPGMA tree of the pan-genomic allelic profiles (n=7) derived for S. 452
marcescens isolates from the Institute for Medical Microbiology, Immunology and 453
Hygiene at the University of Cologne, Germany. Outbreaks and transfer events 454
(Cologne-1 to Cologne-5) identified prior to our study are highlighted by color, with 455
relevant microbiological, host-associated and environmental metadata displayed to 456
the right. The UPGMA tree which was built using a similarity coefficient based on 457
categorical values expressed as a percentage. Isolates originating from inanimate 458
surfaces are highlighted in blue. 459
460
Figure 3 UPGMA tree of the pan-genomic allelic profiles (n=4) derived for S. 461
marcescens isolates from the University Hospital of Freiburg, Germany. A single 462
major outbreak event generated all strains except four (red and non-boxed). 463
Relevant microbiological, host-associated and environmental metadata are displayed 464
to the right. The UPGMA tree was built using a similarity coefficient based on 465
categorical values expressed as a percentage. Note that in this case multiple 466
isolates were included for 8 different individuals. Isolates originating from inanimate 467
surfaces are highlighted in blue. 468
469
Figure 4 Review of quality parameters for the S. marcescens specific whole genome 470
sequences used to construct the wgMLST reference database. 471
Figure 4A Correlation between number of clusters and similarity cutoff values 472
for the founding S. marcescens wgMLST database. The cluster index was 473
based on the average number of alleles being different between closely 474
related strain pairs. The analysis was performed using all WGS listed in 475
Supplementary Table 2. 476
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Figure 4B Correlation between the numbers of pairwise allelic differences and 477
their frequency of occurrence. 478
Figure 4C Minimum spanning tree based on the pan-genomic allelic profiles 479
of 299 S. marcescens isolates, representing the reference set used to create 480
the wgMLST database. Colors highlight closely related isolates, numbers of 481
allelic differences are indicated on the lines connecting the various types. 482
483
Figure 5 Minimum spanning trees for the S. marcescens isolates from Groningen, 484
Cologne and Freiburg built from the pan-genomic allelic profiles. Colors of the circles 485
identify the epidemiological clusters and cases of transmission. Figures on the axes 486
identify the numbers of allelic differences between the connected isolates. Circle size 487
is associate with the number of isolates per type. The figure implies that there are no 488
clusters extending across hospitals. Color codes are specific for the three different 489
panels and should not be compared between panels. 490
491
Figure 6 Overall genomic population structure of S. marcescens based on a 492
combined analysis of our epidemiologically related isolates and the reference 493
genomes that were used to construct the wgMLST scheme. Note the extended 494
number of singletons and the occurrence of epidemic clones seemingly originating 495
from several of such singletons. Green bullets represent isolates from Groningen, 496
red ones the isolates from Cologne and blue ones identify the isolates from Freiburg. 497
498
499
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Figure 1
14.2
7.1
3.2
8.9
2.2
20.6
19.6
100.0
19.7
18.8
100.0
19.9
18.4
100.0
17.5
13.0
1.8
26.5
10.9
100.0
100.0
100.0
100.0
99.9
30.4
97.2
70.3
24.6
9.4
1.9
1.7
0.1
wgMLST (wgMLST)1
00
90
80
70
60
50
40
30
20
10
resistanceaac(6
')-I
c
sul1
tet(
41)
aac(6
')-I
Ic
aadA
1
bla
VIM
-1
bla
OX
A-1
0
mph(A
)
catA
2
cm
lA1
cm
l
AR
R-2
plasmids
ColR
NA
I
IncX
3
IncA
/C2
Cluster
0001
0001
0002
0002
0003
0003
0003
0003
0003
0004
0004
0005
0005
0005
0005
0005
0005
0005
0005
0005
0005
0006
0006
0007
0007
Isolate ID
UMCG-041
UMCG-042
UMCG-025
UMCG-019
UMCG-031
UMCG-037
UMCG-026
UMCG-030
UMCG-018
UMCG-002
UMCG-005
UMCG-011
UMCG-027
UMCG-028
UMCG-039
UMCG-020
UMCG-021
UMCG-022
UMCG-024
UMCG-023
UMCG-040
UMCG-014
UMCG-034
UMCG-016
UMCG-017
UMCG-004
UMCG-006
UMCG-007
UMCG-009
UMCG-010
UMCG-003
UMCG-008
UMCG-012
UMCG-015
UMCG-013
UMCG-001
UMCG-032
UMCG-038
UMCG-035
UMCG-036
UMCG-033
UMCG-029
Gender
F
F
M
M
F
M
M
F
F
M
M
F
M
M
F
F
F
M
M
M
M
F
M
M
F
M
F
F
M
F
M
M
F
F
M
F
M
M
M
F
M
F
Type of Specimen
Faeces
Faeces
Faeces
Faeces
Synovial fluid
Faeces
Faeces
Rectal
Pus thorax
Faeces
Rectal
Urine
Faeces
Faeces
Faeces
Faeces
Faeces
Faeces
Blood culture
Faeces
Faeces
Faeces
Faeces
Sputum
Sputum
Blood culturectal
Faeces
Faeces
Faeces
Urine
Sputum
Sputum
Sputum
Faeces
Sputum
Blood culturectal
Blood culturectal
Faeces
Faeces
Faeces
Blood culturectal
IV line
Ward
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Orthopedics
Childrens general surgery
Neonatal ICU
Neonatal ICU
Childrens ICU
Neonatal ICU
Neonatal ICU
Obstetrics
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Childrens ICU
Childrens special care
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Childrens general surgery
Neonatal ICU
Childrens ICU
Childrens ICU
Neonatal ICU
Neonatal ICU
Childrens special care
Cardiology
Neonatal ICU
Neonatal ICU
Neonatal ICU
Cardiology
Neonatal ICU
Isolation Date
2017-10-30
2017-10-30
2015-07-13
2015-01-19
2016-04-05
2017-07-04
2015-07-13
2015-12-28
2014-12-14
2014-08-18
2014-09-03
2014-10-14
2015-11-17
2015-11-17
2017-10-23
2015-05-26
2015-05-26
2015-05-26
2015-06-10
2015-06-08
2017-10-26
2014-10-30
2017-06-06
2014-12-09
2014-12-15
2014-08-29
2014-09-15
2014-09-22
2014-09-25
2014-10-11
2014-08-25
2014-09-23
2014-10-16
2014-11-24
2014-10-28
2014-06-27
2016-06-21
2017-07-18
2017-06-29
2017-06-29
2016-06-22
2015-12-17
Age (years)
0
0
0
0
77
0
0
0
15
0
0
37
0
0
0
0
0
0
0
0
0
0
0
15
0
0
0
0
0
0
0
0
0
0
0
1
38
0
0
0
47
0
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Figure 2
100.0
100.0
24.4
9.3
1.8
100.0
13.1
100.0
2.1
1.8
wgMLST (wgMLST)
100
80
60
40
20
resistance
aa
dA
2
aa
dB
aa
c(6
')-I
c
ca
tA1
su
l1
tet(
41
)
tet(
A)
dfr
A1
6
tet(
U)
plasmids
IncH
I2
IncH
I2A
Cluster
0001
0001
0001
0001
0001
0001
0003
0003
0002
0002
0002
0002
0002
0004
0004
0005
0005
Outbreak Info
Cologne-5
Cologne-5
Cologne-5
Cologne-5
Cologne-5
Cologne-5
Cologne-1
Cologne-1
Singleton-2
Singleton-1
Cologne-2
Cologne-2
Cologne-2
Cologne-2
Cologne-2
Cologne-4
Cologne-4
Cologne-3
Cologne-3
Isolate ID
AML_0403
AML_0404
AML_0402
AML_0401
AML_0400
AML_0405
AML_0005
AML_0001
AML_0029
AML_0406
AML_0214
AML_0213
AML_0216
AML_0217
AML_0215
AML_0027
AML_0028
AML_0293
AML_0294
Gender
M
F
M
M
F
F
M
F
M
M
M
M
M
F
M
F
Type of Specimen
Nose/Throat swab
Nose/Throat swab
Umbilical swab
Nose/Throat swab
Nose/Throat swab
Nose/Throat swab
Gastric juice
Pleural aspirate
Rectal swab
Siphon (environmental)
Rectal swab
Rectal swab
Weighing scale (environmental)
Kleenex box (environmental)
Ear swab
Rectal swab
Gastric juice
Nose/Throat swab
Rectal swab
Ward
Neonatal ward
Neonatal ward
Neonatal ward
Neonatal ward
Neonatal ward
Neonatal ward
Neonatal ICU
Neonatal ICU
Pediatric general
Neonatal ward
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ward
Pediatric general
Pediatric general
Neonatal ICU
Neonatal ward
Isolation Date
2017-10-12
2017-10-05
2017-09-17
2017-11-27
2017-10-19
2017-12-07
2014-11-27
2014-11-25
2015-08-20
2017-11-01
2017-01-12
2017-01-16
2017-01-20
2017-01-20
2017-01-16
2015-08-10
2015-08-13
2017-12-12
2017-12-19
Age (years)
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
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Figure 3
3.3
100.0
100.0
100.0
100.0
100.0
100.0
100.0
100.0
100.0
100.0
100.0
100.0
100.0
99.9
100.0
99.9
99.9
99.9
99.4
22.5
1.5
wgMLST (wgMLST)
10
0
90
80
70
60
50
40
30
20
10
resistance
aa
c(6
')-I
c
tet(
41
)
Cluster
0001
0001
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
0002
Patient Info
patient_D
patient_A
patient_I
patient_E
patient_D
patient_F
patient_A
patient_B
patient_B
patient_C
patient_A
patient_A
patient_A
patient_E
patient_D
patient_G
patient_G
patient_H
patient_D
patient_I
patient_B
patient_E
patient_C
patient_C
patient_C
patient_A
patient_A
patient_C
patient_F
patient_H
Isolate ID
Smarc00428
Smarc00429
Smarc00478
Smarc00449
Smarc00455
Smarc00438
Smarc00466
Smarc00442
Smarc00477
Smarc00445
Smarc00452
Smarc00457
Smarc00462
Smarc00431
Smarc00432
Smarc00433
Smarc00434
Smarc00435
Smarc00437
Smarc00443-A
Smarc00443-B
Smarc00444
Smarc00446
Smarc00448
Smarc00450
Smarc00456
Smarc00458
Smarc00459
Smarc00460
Smarc00464
Smarc00465
Smarc00468
Smarc00469
Smarc00476
Smarc00436
Smarc00451
Smarc00461
Smarc00441
Smarc00454
Smarc00439-A
Smarc00440-S12
Smarc00481
Smarc00475
Smarc00439-B
Smarc00463
Smarc00479
Smarc00480
Smarc00430
Smarc00453
Smarc00474
Smarc00447
Gender
M
M
M
M
M
M
M
F
M
M
M
F
M
unknown
F
F
M
M
M
M
M
F
M
M
F
M
F
F
M
M
F
F
M
M
M
M
M
M
M
M
F
F
M
M
Type of Specimen
Blood culture
Nose/Throat swab
blood culture
Anal swab
Thermometer (environmental)
Anal swab
Anal swab
Anal swab
Wound swab
Nose/Throat swab
Nose/Throat swab
Nose/Throat swab
Anal swab
Nose/Throat swab
Anal swab
Blood culture
Nose/Throat swab
Anal swab
Nose/Throat swab
Anal swab
Anal swab
Anal swab
Nose/Throat swab
Thermometer (environmental)
Secretion
Milk pump (environmental)
Nose/Throat swab
Anal swab
Nose/Throat swab
Anal swab
Anal swab
Anal swab
Liquid other
Nose/Throat swab
Anal swab
Anal swab
Anal swab
Anal swab
Thermometer (environmental)
Anal swab
Anal swab
Swab
Nose/Throat swab
Anal swab
Anal swab
Thermometer (environmental)
Thermometer (environmental)
Swab
Thermometer (environmental)
Wound swab
Nose/Throat swab
Ward
Pediatric general
Emergency
Pediatric general
Neonatal ICU
Neonatal ICU
Neonatal ICU
Pediatric general
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Pediatric general
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Pediatric general
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Pediatric general
Pediatric general
Pediatric general
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Neonatal ICU
Pediatric general
Neonatal ICU
Neonatal ICU
Emergency
Neonatal ICU
Neonatal ICU
Pediatric general
Clinical Presentation
bacteraemia
infection
bacteraemia
colonisation
hospital surface
colonisation
colonisation
colonisation
colonisation
colonisation
bacteraemia
colonisation
colonisation
colonisation
colonisation
bacteraemia
bacteraemia
colonisation
colonisation
colonisation
colonisation
colonisation
colonisation
hospital surface
bacteraemia
hospital surface
colonisation
colonisation
colonisation
colonisation
colonisation
infection
colonisation
colonisation
bacteraemia
bacteraemia
colonisation
colonisation
hospital surface
colonisation
colonisation
colonisation
colonisation
colonisation
colonisation
hospital surface
hospital surface
colonisation
hospital surface
infection
unknown
Isolation Date
2015-09-16
2015-10-12
2015-12-13
2015-11-02
unknown
2015-10-19
2015-11-20
2015-10-18
2015-12-09
2015-10-22
2015-11-02
2015-10-26
2015-11-17
2015-10-12
2015-10-18
2015-10-16
2015-10-19
2015-10-18
2015-10-18
2015-10-18
2015-10-18
2015-10-18
2015-10-21
2015-10-21
2015-11-02
unknown
2015-10-26
2015-11-04
2015-11-05
2015-11-20
2015-11-20
2015-11-23
2015-11-23
2015-12-09
2015-10-19
2015-11-02
2015-11-06
2015-10-18
unknown
2015-10-18
2015-10-18
2015-11-30
2015-11-30
2015-10-18
2015-11-17
2015-12-10
2015-12-10
2015-10-12
unknown
2015-11-30
2015-10-16
Age (years)
4
0
12
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
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Figure 4A
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Figure 4B
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Figure 4C
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Figure 5
Groningen
Cologne
Freiburg
1.00
1.00
3016.00
3193.00
1.00
3231.00
1.00
3243.00
3348.00
3384.00
AML_0401, AML_0402, AML_0403, AML_0404
AM
AML_0405
AML_0001, AML_0005
AML_0293
AML_0294
AML_0213, AML_0214, AML_0216, AML_0217
AML_0215
AML_0406
AML_0029
AML_0027, AML_0028
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
2.00
2.00
18.00
3135.00
3452.00
3630.00
0431, Smarc00432, Smarc00433, Smarc00434, ...40-S12, Smarc00481, Smarc00475
Smarc00479
Smarc00454
Smarc00436
Smarc00438
Smarc00441
Smarc00455
Smarc00439-B
Smarc00480
Smarc00430
Smarc00453
Smarc00474
Smarc00447
Smarc00478
Smarc00428, Smarc00429
1.00
1.00
1.00
2.00
2.00
2808.00
2987.00
1298.00
124.00
3159.00
3084.00
3103.00
1.00
2996.00
2.00
3000.00
3004.00
3091.00
3100.00
1.00
3160.00
3237.00
3243.00
3254.00
3258.00
3185.00
3284.00
3350.00
3355.00
3373.00
3378.00
UMCG-004, UMCG-006, UMCG-007, UMCG-009, UMCG-010
UMCG-008
UMCG-003
UMCG-012
UMCG-015
UMCG-013
UMCG-001
UMCG-035, UMCG-036
UMCG-038
UMCG-032
UMCG-025
UMCG-037
UMCG-023
UMCG-020, UMCG-021, UMCG-022, UMCG-024
UMCG-002
UMCG-005
UMCG-039
UMCG-026
UMCG-011
UMCG-027
UMCG-028
MCG-042
UMCG-018
UMCG-041
UMCG-030
UMCG-014
UMCG-034
UMCG-019
UMCG-040
UMCG-016, UMCG-017
UMCG-033
UMCG-031
on February 11, 2019 by guest
http://jcm.asm
.org/D
ownloaded from
http://jcm.asm.org/
Figure 6
Groningen
Cologne
Freiburg
on February 11, 2019 by guest
http://jcm.asm
.org/D
ownloaded from
http://jcm.asm.org/